Loop material for loop and hook type fastener used in a disposable article or garment

ABSTRACT

A loop material for a hook and loop type fastener is a composite nonwoven. The composite nonwoven consists of a loop layer, a backing layer, and a plurality of bond regions. The loop layer may be a carded nonwoven of thermoplastic crimped staple fiber. The staple fiber may be between 1.5 to 6.0 dTEX. The loop layer may have a basis weight of between 10 and 35 g/m 2 . The backing layer may be a spunbond or spunmelt nonwoven having a basis weight of 5 to 30 g/m 2 . The loop layer may be superimposed face-to-face with the backing layer. The plurality of bond regions joins the loop layer to the backing layer and rendering said bond regions substantially air impermeable. The bond regions comprise between 35 to 55% of a surface area of the loop material.

RELATED APPLICATIONS

This application claims the benefit of co-pending U.S. application Ser.No. 12/060,590 filed Apr. 1, 2008 which claims the benefit of U.S.Provisional Application Ser. No. 60/912,244 filed Apr. 17, 2007. Bothrelated applications, in their entireties, are incorporated herein byreference.

FIELD OF THE INVENTION

The present invention is directed to a loop material for a loop and hooktype fastener used in a disposable article or garment.

BACKGROUND OF THE INVENTION

The use of hook and loop fastener devices in consumer and industrialapplications is widely known. Examples of such applications includedisposable hygiene absorbent articles such as diapers, disposablegarments such as surgical gowns, and the like.

In general, a hook and loop fastener device comprises a hook componentand a loop component. The hook component includes a plurality ofhook-shaped members anchored to a base material. The loop componentincludes a plurality of upstanding loop members projecting outwardlyfrom a backing material. The hook-shaped members are designed to engagethe loop members in order to provide a strong mechanical bond therebetween. The hook members and the loop members can typically be engagedand disengaged repeatedly.

However, when the hook and loop fastener device is intended to be usedin a disposable hygiene absorbent article or a disposable garment, a lowcost loop component, which adequately functions to provide a resealablemechanical closure for a limited number of applications, is desirable.There is no need for the loop component of a disposable article topossess long term capability for repetitious engagements anddisengagements with the hook component because such articles only have ashort life span. However, the loop component used in conjunction withthe hook component should provide a relatively high peel strength, and arelatively high shear strength, i.e. it should secure closure for alimited number of use cycles.

There are a variety of loop materials available. Typical loop materialsinclude knit or nonwoven fabrics laminated to a layer of film forsupport. These loop materials are typically processed on diaper lines byunwinding the material from a roll, applying adhesive to the back, filmside of the loop material, feeding the material over a perforated metalcylinder which holds the material in place with vacuum suction, cuttingthe material in strips as it is held against the cylinder and applyingthe strips to diaper backsheet material that is fed in parallel throughthe diaper assembly line.

Polypropylene is preferred for production of nonwoven materials fordiaper applications due to their relatively low cost, soft feel,availability, and ease of processing. For nonwoven loop materials itwould be desirable to eliminate the use of a film support layer in orderto further reduce the cost and improve the softness and flexibility ofthe loop material.

However, several problems have been encountered which have limited theuse of nonwovens for use as loop fastening materials. These will bediscussed in turn.

Typical nonwoven materials are too air permeable. Such high permeabilitymaterials cannot be held in place effectively during the strip cuttingoperation on the typical existing diaper line vacuum cylinders. In orderto use such highly permeable materials, extensive modification to thevacuum cylinders and associated equipment would be required.

Typical polypropylene based nonwovens are susceptible to compression.When nonwoven loop materials are wound into rolls and stored for aperiod of time, the loop regions can become permanently compressed. Whena roll of nonwoven loop material is unwound, processed on the diaperline and pieces are cut and attached to the diaper backsheet, the loopmay be so flat as to no longer to be useful as an effective fasteningmaterial.

The nonwoven fibers and filaments must be bonded together to secure thestructure together as well as to leave regions of unbonded fibers orloops available for fastening with a hook counterpart. If aninsufficient percentage of the planar area of the nonwoven is bondedtogether, nonwoven fibers can be easily pulled free from the structureupon retraction of the hook when opening the fastener. If too high apercentage of the planar area of the nonwoven is bonded together thereis insufficient loop fiber available for hook engagement and thefastening performance is too low. In addition, the bonding pattern has alarge impact on the ease of hook engagement and therefore the fasteningperformance.

There is a need for low cost nonwovens for use as a loop fasteningmaterial for use in hygiene applications such as diapers that overcomethese problems.

SUMMARY OF THE INVENTION

A loop material for a hook and loop type fastener is a compositenonwoven. The composite nonwoven consists of a loop layer, a backinglayer, and a plurality of bond regions. The loop layer may be a cardednonwoven of thermoplastic crimped staple fiber. The staple fiber may bebetween 1.5 to 6.0 dTEX. The loop layer may have a basis weight ofbetween 10 and 35 g/m². The backing layer may be a spunbond or spunmeltnonwoven having a basis weight of 5 to 30 g/m². The loop layer may besuperimposed face-to-face with the backing layer. The plurality of bondregions joins the loop layer to the backing layer and rendering saidbond regions substantially air impermeable. The bond regions comprisebetween 35 to 55% of a surface area of the loop material.

DESCRIPTION OF THE DRAWINGS

For the purpose of illustrating the invention, there is shown in thedrawings a form that is presently preferred; it being understood,however, that this invention is not limited to the precise arrangementsand instrumentalities shown.

FIG. 1 is a cross sectional view of the nonwoven composite madeaccording to the present invention.

FIG. 2 is a top plan view of one of the embodiments of the nonwovencomposite made according to the present invention.

FIG. 3 is a top plan view of one of the embodiments of the nonwovencomposite made according to the present invention.

FIG. 4 is a top plan view of “islands”.

FIG. 5 is a schematic illustration of a method of manufacturing thepresent invention.

FIG. 6 is an illustration associated with the example below.

DESCRIPTION OF THE INVENTION

Referring to the drawing wherein like numerals indicate like elements,there is shown in FIG. 1 an embodiment of the nonwoven composite 10.Nonwoven composite 10 includes a loop layer 12, a backing layer 14, anda plurality of bond regions 16. Each of these elements will be discussedin greater detail below.

Nonwoven composite 10 is intended to be the loop component of a hook andloop type fastener (not shown) for a disposable article/garment.Disposable article/garment includes disposable hygiene absorbentarticles (such as diapers), and disposable garments (such as surgicalgowns). Disposable, generally, refers to single use.

In the composite nonwoven 10, loop layer 12 and backing layer 14 are inface-to-face contact and are joined together at bond regions 16.Nonwoven composite 10 may include at least two different nonwovenmaterials. The loop layer 12 in the non-bonded areas forms a ‘mound’whereby the loop layer nonwoven is open and adapted for hook engagement.The loop layer 12 in the bonded areas is flat whereby the loop layer isclosed and not adapted for hook engagement. The total air permeabilityof the composite nonwoven 10 should not exceed 1500 l/m²/s. In oneembodiment, the permeability should not exceed 1300 l/m²/s. In anotherembodiment, the permeability should be at 800 l/m²/s. The upper limitson permeability represent a threshold where the composite nonwovenfunctions well in a diaper manufacturing process (as discussed above),and the lower limit represents a threshold where the composite nonwovenhas sufficient suppleness (i.e., does not feel stiff like a film).Permeability is measured using an Air Permeability Tester III, Model FX3300 from Textest AG of Zurick, Switzerland.

Loop layer 12 is adapted to, among other things, engage the hooks (notshown) of the hook and loop type fastener. In one embodiment, the looplayer 12 may be a carded nonwoven made of thermoplastic crimped staplefibers. In one embodiment, the staple fibers may have a dTEX in therange of 1.5 to 6.0. The basis weight of the carded nonwoven may be inthe range of 10 to 35 g/m². Alternatively, the basis weight may be inthe range of 18 to 27 g/m². Prior to its inclusion in the compositenonwoven 10, the carded nonwoven may be non-bonded (preferred) orbonded. If bonded, bonding may be accomplished by any know means(bicomponent fibers; point bonding with heat, ultrasonic, microwave;adhesives; and the like); but preferably, bonding would be accomplishedby the use of bicomponent fibers. The thermoplastic, as used herein,refers to any thermoplastic material. Thermoplastic materials include,but are not limited to, polyolefins, polyesters, nylons, andcombinations thereof. Polyolefins include, but are not limited to:polyethylene, polypropylene, polybutene, polymethylpentene, copolymersthereof and blends thereof. Polyesters include, but are not limited to:PET, PBT, copolymers thereof and blends thereof. In one embodiment, thethermoplastic material is polypropylene.

The backing layer 14 is adapted to, among other things, hold the fibersof the loop layer 12 in place, provide a surface so that the loop layer12 may be secured to the article/garment (not shown), and facilitateassembly of the article/garment. In one embodiment, the backing layermay be a spunbonded or spunmelt nonwoven made of thermoplasticfilaments. Spunbond or spunmelt nonwoven, as used herein, refers to anonwoven made by a spunbond process or a spunmelt process. The spunmeltprocess is a combination of the spunbond (S) and meltblown (M)processes. The spunmelt nonwoven may have a structure of SM or SMS orSMMS or the like. The basis weight of the spunbonded or spunmeltnonwoven may be in the range of 5 to 30 g/m². Alternatively, the basisweight may be in the range of 11 to 17 g/m². The spunbond or spunmeltnonwoven may be adjusted to reduce air permeability. Reduced airpermeability is useful in the article/garment manufacturing process whenthe composite nonwoven is affixed to the article/garment. The backinglayer 14, when produced, may be calendered before assembly of compositenonwoven 10. After this calendering, one side may be “smooth,” i.e., nodimples from the engraved roller. The smooth side may be an exposed sideof the composite nonwoven 10 and may be printed thereon. Thethermoplastic, as used herein, refers to any thermoplastic material.Thermoplastic materials include, but are not limited to, polyolefins,polyesters, nylons, and combinations thereof. Polyolefins include, butare not limited to: polyethylene, polypropylene, polybutene,polymethylpentene, copolymers thereof and blends thereof. Polyestersinclude, but are not limited to: PET, PBT, copolymers thereof and blendsthereof. In one embodiment, the thermoplastic material is polypropylene.

Bond regions 16, as used herein, refers to the areas where the looplayer and the backing layer are joined together and where the nonwovencomposite is substantially impermeable. ‘Substantially impermeable’refers to the permeability relative to the non-bonded areas, where airmay pass through the nonwoven composite. In the bonded areas, no air maypass (or no more than 5% of the air that would pass through thenon-bonded area), whereas in the non-bonded areas air may pass throughthe nonwoven composite. The bond regions 16 may comprise about 35 to 55%of the surface area of the loop material. The bond regions 16 maycomprise 40-50% of the surface area of the loop material. The bondregions 16 may be lines or waves (continuous or discontinuous) asillustrated, for example, in FIGS. 2, and 3; but are not “islands” 19 asillustrated, for example, in FIG. 4. In one embodiment, the bond regionsare disposed in the cross machine direction. Hooks (not shown) will notengage the nonwoven composite in the bonded areas, but the hooks willengage the nonwoven composite in the non-bonded areas. As noted in FIG.1, the combined height of the loop layer 12 and the backing layer 14 inthe bonded areas is less than the height of the backing layer 14 in thenon-bonded areas.

When the bond regions 16 are lines or waves, loop length is the distancebetween bond regions. Loop lengths in the loop material may be equal orsubstantially equal. Loop lengths, in the machine direction, may be 1-4mm or 2-3 mm. The loop height is the distance between the backing layer14 and the uppermost part of the loop layer 12. The loop height issubstantially equal between non-bonded areas.

The composite nonwoven 10 is manufactured as follows, see FIG. 5: Afirst web 20, spunmelt or spunbond, is formed by extruding filamentsfrom thermoplastic resin. This web is then consolidated by calendering.A second web 22 is produced by carding crimped staple fibers to producea web that is not consolidated. The two webs are then superimposed(i.e., face-to-face). The resulting web composed of the two superimposedwebs is passed through a hot calender 24 (roll 26 being, for example, anengraved roller, and roll 28 being, for example, a smooth roller) toachieve the following results: consolidation of the carded web bybonding the crimped staple fibers at multiple zones, joining both webstogether along multiple bond zones. In the calendering process, the webbonding will be at or near the melting point of the thermoplasticpolymer from which the nonwoven is produced. It is important to processat a temperature and pressure sufficient to allow the proper bonding ofthe webs together. Thereafter, the composite nonwoven is wound-up 30.

EXAMPLE Comparison of 180 Degree Peel Test Results

The 180 Degree Peel results are compared for composite nonwovens thatwere produced with a relatively low percentage of area bonding and abonding pattern according to the present invention. Peel testing wasconducted using a tensile tester, Model No. MTC Alliance RT/5 from MTSSystems Corporation of Eden Prairie, Minn.

Master rolls of each composite nonwovens were produced using the bondingpatterns, noted below, and then slit into rolls and wound at the samelevel of tension. One slit roll of each bond pattern was then stored formore than two weeks. Samples were then taken from similar sites withineach roll and tested for 180 degree peel, see FIG. 6.

The 180° peel strength test involves attaching a hook component to aloop component of a hook and loop fastening system and then peeling thehook component from the loop component at a 180° angle. The maximum loadneeded to disengage the two components is recorded in newtons.

Slit Sample Roll 1 SMS base layer: 14 g/m² Carded fiber top layer: 23g/m² Bonded Area: 17.4% Engraving: Islands (See FIG. 4) 180 Degree peeltest conducted with the use of Aplix 94x prototype hook (13 mm wide tapewith mushroom shaped hooks with a density of 385 hooks/cm²) Samplestaken from roll 17 days after slitting master roll Slit Sample Roll 2SMS base layer: 14 g/m² Carded fiber top layer: 23 g/m² Bonded Area: 42%Engraving: Horizontal discontinuous waves (See FIG. 3) 180 Degree peeltest conducted with the use of Aplix 94x prototype hook (13 mm wide tapewith mushroom shaped hooks with a density of 385 hooks/cm²) Samplestaken from roll 21 days after slitting master roll Sample Master SiteRoll A B C D Slit Sample Roll 1 180° 5.6 3.5 3.0 4.4 2.8 Peel, N* SlitSample Roll 2 180° 5.3 5.3 5.0 5.3 4.9 Peel, N* *average of ten datapoints

The present invention may be embodied in other forms without departingfrom the spirit and the essential attributes thereof, and, accordingly,reference should be made to the appended claims, rather than to theforegoing specification, as indicated the scope of the invention.

1. A loop material for a hook and loop type fastener comprising: acomposite nonwoven consisting of a loop layer of a non-bonded carded webof thermoplastic crimped staple fibers, said staple fibers being between1.5 to 6.0 dTEX, and said carded web having a basis weight of between 10and 35 g/m2; a backing layer of a spunmelt nonwoven having a basisweight of 5 to 30 g/m2, said loop layer being superimposed face-to-facewith said backing layer; and a plurality of bond regions joining saidloop layer to said backing layer; said composite nonwoven having an airpermeability not exceeding 1500 l/m2/s.
 2. The loop material of claim 1wherein said composite nonwoven having an air permeability not exceeding1300 l/m2/s.
 3. The loop material of claim 2 wherein said compositenonwoven having an air permeability in the range of 800 to 1300 l/m2/s.4. The loop material of claim 1 wherein said bond regions being in theform of continuous or discontinuous lines or waves.
 5. The loop materialof claim 4 wherein said bond regions extend in a cross machinedirection.
 6. The loop material of claim 1 wherein a height of said bondregion being less than the height of said backing layer.
 7. The loopmaterial of claim 1 wherein said bond regions being substantially airimpermeable.
 8. The loop material of claim 7 wherein substantially airimpermeable being an air permeability of said bond region being no morethan 5% of an air permeability of a non-bond region.
 9. The loopmaterial of claim 1 wherein a plurality of loops being formed in saidloop layer between said bond regions, said loops extending away fromsaid backing layer to a substantially equal height.
 10. The loopmaterial of claim 1 wherein a loop length being a distance between bondregions, and said loop length being in the range of 1-4 mm.
 11. A loopmaterial for a hook and loop type fastener comprising: a compositenonwoven consisting of a loop layer of a non-bonded carded web ofpolypropylene crimped staple fibers, said staple fibers being between1.5 to 6.0 dTEX, and said carded web having a basis weight of between 10and 35 g/m2; a backing layer of a polypropylene spunmelt nonwoven havinga basis weight of 5 to 30 g/m2, said loop layer being superimposedface-to-face with said backing layer; and a plurality of bond regionsjoining said loop layer to said backing layer; said composite nonwovenhaving an air permeability not exceeding 1500 l/m2/s.
 12. The loopmaterial of claim 11 where said backing layer having a basis weight ofbetween 10 g/m2 and 14 g/m2.
 13. The loop material of claim 11 wheresaid backing layer having a basis weight of 14 g/m2.
 14. The loopmaterial of claim 11 wherein said bond regions being in the form ofcontinuous or discontinuous lines or waves.
 15. The loop material ofclaim 14 wherein said bond regions extend in a cross machine direction.16. The loop material of claim 11 wherein a height of said bond regionbeing less than the height of said backing layer.
 17. The loop materialof claim 11 wherein said bond regions being substantially airimpermeable.
 18. The loop material of claim 17 wherein substantially airimpermeable being an air permeability of said bond region being no morethan 5% of an air permeability of a non-bond region.
 19. The loopmaterial of claim 11 wherein a plurality of loops being formed in saidloop layer between said bond regions, said loops extending away fromsaid backing layer to a substantially equal height.
 20. The loopmaterial of claim 11 wherein a loop length being a distance between bondregions, and said loop length being in the range of 1-4 mm.